Hostname: page-component-848d4c4894-8kt4b Total loading time: 0 Render date: 2024-06-25T20:28:36.707Z Has data issue: false hasContentIssue false
  • English
  • Français

Global Effects of Tropical Deforestation: Towards an Integrated Perspective

Published online by Cambridge University Press:  24 August 2009

Allison G. Cook ,
Anthony C. Janetos  and
W. Ted Hinds
Allison G. Cook
Affiliation:
AScl Corporation, 1365 Beverly Road, McLean, Virginia 22101, USA
Anthony C. Janetos
Affiliation:
Manager, Global Change Research Program, US Environmental Protection Agency, Washington, DC 20460, USA
W. Ted Hinds
Affiliation:
Technology, Planning, and Analysis Unit, Battelle Pacific Northwest Laboratories, 370 L'Enfant Promenade, 901 D Street SW, Suite 900, Washington, DC 20024-2115, USA.
Get access Rights & Permissions [Opens in a new window]

Extract

Deforestation of the tropical moist forests is taking place at an alarming pace; some experts believe that the entire ecobiome will be virtually destroyed within the next ten years. Although the ultimate ecological effects of tropical deforestation remain controversial, our present scientific understanding is adequate to justify efforts to slow the deforestation trend. The impacts that this trend will probably have on global climate remain unclear, while the effects that it will have on biodiversity will clearly be disastrous. This suggests that the research community should place a high priority on applying data on refugia (documented sites of high endemism and species-richness) to conservation planning, and on investigating the probable combined effects of climatic change and habitat fragmentation on world biodiversity.

Type
Main Papers
Information
Environmental Conservation , Volume 17 , Issue 3 , Autumn 1990 , pp. 201 - 212
Copyright
Copyright © Foundation for Environmental Conservation 1990

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Adams, C. (1904). The postglacial dispersal of the North American biota. Biological Bulletin, 9, pp. 5371.CrossRefGoogle Scholar
Balek, J. (1983). Hydrology and Water Resources in Tropical Regions. Elsevier Science Publishing, New York, NY, USA: 267 pp., illustr.Google Scholar
Breitenbeck, G.A., Blackmer, A.M. & Bremner, J.M. (1980). Effects of different nitrogen fertilizers on emission of nitrous oxide from the soil. Geophysical Research Letters, 7(1), pp. 85–8, illustr.CrossRefGoogle Scholar
Bremner, J.M. & Blackmer, A.M. (1981). Terrestrial nitrification as a source of atmospheric nitrous oxide. Pp. 151–70 in Denitrification, Nitrification, and Atmospheric Nitrous Oxide (Ed. Delwiche, C.C.). John Wiley & Sons, New York, NY, USA: xi + 286 pp., illustr.Google Scholar
Brown, K.S., Sheppard, P.M. & Turner, J.R.G. (1974). Quaternary refuges in tropical America: evidence from race formation in Heliconius butterflies. Proceedings of the Royal Society of London (B), 187, pp. 6978, illustr.Google Scholar
Brown, S. (1988). Science, 241, p. 1739 (letter).CrossRefGoogle Scholar
Brown, S. & Lugo, A.E. (1982). The storage and production of organic matter in tropical forests and their role in the global carbon cycle. Biotropica, 14(3), pp. 161–79, illustr.CrossRefGoogle Scholar
Buschbacher, R.J. (1986). Tropical deforestation and pasture development. BioScience, 36(1), pp. 22–7, illustr.CrossRefGoogle Scholar
Carcasson, R.H. (1964). A preliminary survey of African butterflies. East African Wildlife, 11, pp. 122–57, illustr.CrossRefGoogle Scholar
CEQ— see Council on Environmental Quality.Google Scholar
Colinvaux, P.A. (1987). Amazon diversity in light of the paleoecological record. Quaternary Science Reviews, 6(2), pp. 93114, illustr.CrossRefGoogle Scholar
Council on Environmental Quality (cited as CEQ). (1980). The Global 2000 Report to the President: the Technical Report. US Government Printing Office, Washington, DC, USA: xxxvii + 721 pp., appendices, illustr.Google Scholar
Crutzen, P.J. (1987). Role of the tropics in atmospheric chemistry. Pp. 107–32 in The Geophysiology of Amazonia: Vegetation and Climate Interactions (Ed. Dickinson, R.E.). John Wiley & Sons, New York, NY, USA: xvii + 526 pp., illustr.Google Scholar
Detwiler, R.P. & Hall, C.A.S. (1988). Tropical forests and the global carbon cycle. Science, 239, pp. 42–7.CrossRefGoogle ScholarPubMed
Diamond, A.W. & Hamilton, A.C. (1980). The distribution of forest passerine birds and Quaternary climate change in tropical Africa. Journal of Zoology (London), 191, pp. 379402, illustr.CrossRefGoogle Scholar
Durning, A. (1989). Cradles of life. World Watch, 2(3), pp. 3040, illustr.Google Scholar
Emanuel, W.R., Shugart, H.H. & Stevenson, M.P. (1985). Climatic change and the board-scale distribution of terrestrial ecosystem complexes. Climatic Change, 7(1), pp. 2943, illustr.CrossRefGoogle Scholar
Enhalt, D.H. (1985). Methane in the global atmosphere. Environment, 27(10), pp. 633, illustr.Google Scholar
Environmental Protection Agency (cited as EPA) (1988). The Potential Effects of Global Climate Change on the United States. (Draft Report to Congress.) Office of Policy, Planning, and Evaluation and Office of Research and Development, Washington, DC, USA: viii + 18 chapters, illustr.Google Scholar
Erwin, T.L. (1983). Tropical forest canopies: the last biotic frontier. Bulletin of the Entomological Society of America, 29(1), pp. 14–9, illustr.CrossRefGoogle Scholar
FAO (1985). Tropical Forestry Action Plan. Food and Agriculture Organization of the United Nations, Rome, Italy: vii +159 pp.Google Scholar
Frenzel, B. (1968). The Pleistocene vegetation of northern Eurasia. Science, 161 (3842), pp. 637–49, illustr.CrossRefGoogle Scholar
Gentilli, J. (1949). Foundation of Australian bird geography. Emu, 49, pp. 85130, illustr.CrossRefGoogle Scholar
Goreau, T.J. & Mello, W.Z. de (1988). Tropical deforestation: some effects on atmospheric chemistry. Ambio XVII(4), pp. 275–81, illustr.Google Scholar
Haffer, J. (1969). Speciation in Amazonian forest birds. Science, 165(3889), pp. 131–7, illustr.CrossRefGoogle ScholarPubMed
Haffer, J. (1982). General aspects of the refuge theory. Pp. 623 in Biological Diversification in the Tropics (Ed. Prance, G.T.). Columbia University Press, New York, NY, USA: xvi + 714 pp., illustr.Google Scholar
Henderson-Sellers, A. & Gornitz, V. (1984). Possible climatic impacts of land cover transformations, with particular emphasis on tropical deforestation. Climatic Change, 6(3), pp. 231–57.CrossRefGoogle Scholar
Holdridge, L.R. (1967). Life-zone Ecology. Tropical Science Center, Costa Rica [not available for checking].Google Scholar
Houghton, R.A., Boone, R.D., Fruci, J.R., Hobbie, J.E., Melillo, J.M., Palm, C.A., Peterson, B.J., Shaver, G.R. & Woodwell, G.M. (1987). The flux of carbon from terrestrial ecosystems to the atmosphere in 1980 due to changes in land use: Geographic distribution of the global flux. Tellus, 39(B), pp. 122–39, illustr.CrossRefGoogle Scholar
Hunter, M.L., Jacobson, G.L. & Webb, T. (1988). Paleoecology and the coarse-filter approach to maintaining biological diversity. Conservation Biology, 2(4), pp. 375–83, illustr.CrossRefGoogle Scholar
Jacobson, S.K. & Lafferty, J. (1988). The fourth objective. Conservation Biology, 2(2), p. 221.CrossRefGoogle Scholar
Keeling, C.D., Bacastow, R.B., Bainbridge, A.E., Ekdahl, C.A., Guenther, F.R., Waterman, L.S. & Chin, J.F.S. (1976). Atmospheric carbon dioxide variations at Mauna Loa Observatory, Hawaii. Tellus, 28(6), pp. 538–51, illustr.CrossRefGoogle Scholar
Keller, M, Goreau, T.J., Wofsy, S.C., Kaplan, W.A. & McElroy, M.B. (1983). Production of nitrous oxide and consumption of methane by forest soils. Geophysical Research Letters, 10(12), pp. 1156–9, illustr.CrossRefGoogle Scholar
Keller, M., Jacob, D.J., Wofsy, S.C. & Harriss, R.C. (MS). Effects of Tropical Deforestation on Global and Regional Atmospheric Chemistry. (24 pp. cited with permission.)Google Scholar
Linak, W.P. (in press). N2O emissions from fossil fuel combustion. Proceedings, Joint US EPA/EPRI Symposium on Stationary Combustion NOX Control: illustr.Google Scholar
Lovejoy, T.E. (1979). Refugia, refuges, and minimum critical size: problems in the conservation of neotropical herpetofauna. Pp. 461–4 in The South American Herpetofauna: Its Origin, Evolution, and Dispersal (Ed. Duellman, W.D.). University of Kansas Museum of Natural History, Monograph No 7, 464 pp., illustr.Google Scholar
Lovejoy, T.E. (1982). Designing refugia for tomorrow. Pp. 673–9 in Biological Diversification in the Tropics (Ed. Prance, G.T.). Columbia University Press, New York, NY, USA: xvi + 714 pp., illustr.Google Scholar
McElroy, M.B. & Wofsy, S.C. (1986). Tropical forests: Interactions with the atmosphere. Pp. 3361 in Tropical Rainforests and the World Atmosphere (Ed. Prance, G.T.). Westview Press (for the AAAS), Boulder, Colorado, USA: [not available for checking].Google Scholar
Manabe, S. & Wetherald, R.T. (1980). On the distribution of climate change resulting from an increase in CO2 content of the atmosphere. Journal of the Atmospheric Sciences, 37, pp. 99118, illustr.2.0.CO;2>CrossRefGoogle Scholar
Matson, P.A., Vitousek, P.M., Livingston, G.P. & Swanberg, N.A. (1988). Nitrous oxide flux from Amazon ecosystems: Fertility and disturbance effects. EOS, 69, p. 320 (abstract only).Google Scholar
Mooney, H.A., Vitousek, P.M. & Matson, P.A. (1987). Exchange of materials between terrestrial ecosystems and the atmosphere. Science, 238, pp. 926–32, illustr.CrossRefGoogle ScholarPubMed
Moreau, R.E. (1963). Vicissitudes of the African biomes in the Pliocene. Proceedings of the Zoological Society of London, 141, pp. 395421.CrossRefGoogle Scholar
Moreau, R.E. (1966). The Bird Faunas of Africa and Its Islands. Academic Press, New York, NY, USA: viii + 424 pp., illustr.Google Scholar
Myers, N. (1982). Forest refuges and conservation in Africa, with some appraisal of survival prospects of tropical moist forests throughout the biome. Pp. 658–72 in Biological Diversification in the Tropics (Ed. Prance, G.T.). Columbia University Press, New York, NY, USA: xvi + 714 pp., illustr.Google Scholar
Myers, N. (1984). The Primary Source: Tropical Forests and our Future. W.W. Norton, New York, USA: xiv + 389 pp., illustr.Google Scholar
Myers, N. (1986). Tropical deforestation and a mega-extinction spasm. Pp. 394409 in Conservation Biology. The Science of Scarcity and Diversity (Ed. Soule, M.E.). Sinauer Associates, Sunderland, Massachusetts, USA: xiii + 584 pp., illustr.Google Scholar
Myers, N. (1987). The extinction spasm impending: synergisms at work. Conservation Biology, 1(1), pp. 1421.CrossRefGoogle Scholar
Myers, N. (1988). Tropical deforestation and climatic change. Environmental Conservation, 15(4), pp. 293–8.CrossRefGoogle Scholar
Neftel, A., Moor, E., Oeschger, H. & Stauffer, B. (1985). Evidence from polar ice cores for the increased atmospheric CO2 in the past two centuries. Nature (London), 315(2), pp. 45–7, illustr.CrossRefGoogle Scholar
Patrusky, B. (1988). Dirtying the greenhouse window. Mosaic, 19(3/4), pp. 2535, illustr.Google Scholar
Peters, R.L. & Darling, J.D.S. (1985). The greenhouse effect and nature reserves. BioScience, 35(11), pp. 707–17, illustr.CrossRefGoogle Scholar
Pinker, R.T., Thompson, O.E. & Eck, T.F. (1980). The energy balance of a tropical evergreen forest. Journal of Applied Meteorology, 19(12), pp. 1341–50, illustr.2.0.CO;2>CrossRefGoogle Scholar
Postel, S. (1988). Global view of a tropical disaster. American Forests, 94(11/12), pp. 2533, illustr.Google Scholar
Postel, S. & Heise, L. (1988). Reforesting the earth. Worldwatch Paper No. 83, Worldwatch Institute, Washington DC, USA: 66 pp.Google Scholar
Prance, G.T. (1973). Phytogeographic support for the theory of Pleistocene forest refuges in the Amazon basin, based on evidence from distribution patterns in Caryocaraceae, Chryso-balanaceae, Dichapetlaceae, and Lecythidae. Acta Amazonica, 3(3), pp. 538, illustr.CrossRefGoogle Scholar
Rand, A.L. (1948). Glaciation, an isolating factor in speciation. Evolution, 2, pp. 314–21, illustr.CrossRefGoogle ScholarPubMed
Ramanathan, V., Cicerone, R.J., Singh, H.B. & Kiehl, J.T. (1985). Trace gas trends and their potential role in climate change. Journal of Geophysical Research, 90, pp. 5547–66, illustr.CrossRefGoogle Scholar
Salati, E. & Vose, P.B. (1983). Depletion of tropical rainforests. Ambio, 12(2), pp. 6771, illustr.Google Scholar
Salati, E. & Vose, P.B. (1984). Amazon basin: a system in equilibrium. Science, 225(4658), pp. 129–38, illustr.CrossRefGoogle Scholar
Salati, E., Victoria, R.L., Martinelli, L.A. & Richey, J.E. (1989). Deforestation and its role in possible changes in the Brazilian Amazon. Pp. 159–60 in Global Change and Our Common Future: Papers from a Forum (Ed. DeFries, R.S. & Malone, T.F.). National Academy Press, Washington, DC, USA: xiii + 219 pp., illustr.Google Scholar
Schlesinger, W.H. (1989). The role of ecologists in the face of global change. (Editorial.) Ecology, 70(1), p. 1.CrossRefGoogle Scholar
Schneider, C.S. (1989). Global warming: is it real and should it be a part of a global change programme? Pp. 209–19 in Global Change and Our Common Future: Papers From a Forum (Ed. DeFries, R.S. & Malone, T.F.). National Academy Press, Washington, DC, USA: xiii + 219 pp., illustr.Google Scholar
Seidel, S. & Keyes, D. (1983). Can We Delay A Greenhouse Warming? Office of Policy Analysis, Office of Policy and Resources Management, US EPA, Washington, DC, USA: various pagings, illustr.Google Scholar
Seiler, W. & Conrad, R. (1987). Contributions of tropical ecosystems to the global budgets of trace gases, especially CH4, H2, CO and N2O. Pp. 133–63 in The Geophysiology of Amazonia: Vegetation and Climate Interactions (Ed. Dickinson, R.E.). John Wiley & Sons, New York, NY, USA: xvii + 526 pp., illustr.Google Scholar
Seiler, W. & Crutzen, P.J. (1980). Estimates of gross and net fluxes between the biosphere and atmosphere from biomass burning. Climatic Change, 2, pp. 207–48, illustr.CrossRefGoogle Scholar
Shaffer, M.L. (1981). Minimum population sizes for species conservation, BioScience, 31(2), pp. 131–4.CrossRefGoogle Scholar
Swank, W.T. & Douglass, J.E. (1974). Streamflow greatly reduced by converting deciduous hardwood stands to pine. Science, 185(4154), pp. 857–9, illustr.CrossRefGoogle ScholarPubMed
Terborgh, J. (1986). Keystone plant resources in the tropical forest. Pp. 331–42 in Conservation Biology: the Science of Scarcity and Diversity (Ed. Soule, M.E.). Sinauer Associates, Sunderland, Massachusetts, USA: xiii + 584 pp., illustr.Google Scholar
Whittaker, R.H. & Likens, G.E. (1973). Carbon in the biota. Pp. 281302 in Carbon in The Biosphere (Eds Woodwell, G.M. & Pecan, E.V.). US Atomic Energy Commission, Washington, DC, USA: [not available for checking].Google Scholar
WCEDsee World Commission on Environment and Development.Google Scholar
Wilson, E.O. (1985). The biological diversity crisis. BioScience, 35(11), pp. 700–6, illustr.CrossRefGoogle Scholar
Woodwell, G.M., Hobbie, J.E., Houghton, R.A., Melillo, J.M., Moore, B., Peterson, B.J. & Shaver, G.R. (1983). Global deforestation: contribution to atmospheric carbon dioxide. Science, 222(4628), pp. 1081–6, illustr.CrossRefGoogle ScholarPubMed
World Commission on Environment and Development (WCED) (1987). Our Common Future. Oxford University Press, Oxford, England, UK, and New York, NY, USA: xv + 347 pp. + appendices.Google Scholar
World Resources Institute (1986). World Resources 1986. (The World Resources Institute and the International Institute for Environment and Development.) Basic Books, New York, NY, USA: [not available for checking].Google Scholar
Wuebbles, D.J. & Edmonds, J. (1988). A Primer on Greenhouse Gases. US Department of Energy, Washington, DC, USA: viii + 100 pp.Google Scholar
Zimmerman, P.R. & Greenberg, J.P. (1982). Termites: a potentially large source of atmospheric methane, carbon dioxide, and molecular hydrogen. Science, 218(4572), pp. 563–5, illustr.CrossRefGoogle ScholarPubMed